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Protection and Security
How to be a paranoidor just think like one
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Leaking information
Stealing 26.5 million veteran’s data
Data on laptop stolen from employee’s home (5/06) Veterans’ names Social Security numbers Dates of birth
Exposure to identity theft
CardSystems exposes data of 40 million cards (2005) Data on 70,000 cards downloaded from ftp server
These are attacks on privacy (confidentiality, anonymity)
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The Sony rootkit
“Protected” albums included Billie Holiday Louis Armstrong Switchfoot The Dead 60’s Flatt & Scruggs, etc.
Rootkits modify files to infiltrate & hide System configuration files Drivers (executable files)
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The Sony rootkit
Sony’s rootkit enforced DRM but exposed computer CDs recalled Classified as spyware by anti-virus software Rootkit removal software distrubuted Removal software had exposure vulnerability New removal software distrubuted
Sony sued by Texas New York California
This is an attack on integrity
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The Problem
Types of misuse Accidental Intentional (malicious)
Protection and security objective Protect against/prevent misuse
Three key components: Authentication: Verify user identity Integrity: Data has not been written by unauthorized entity Privacy: Data has not been read by unauthorized entity Freshness: Data read is the latest written
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Have you used an anonymizing service?
1. Yes, for email
2. Yes, for web browsing
3. Yes, for something else
4. No
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What are your security goals?
Authentication User is who s/he says they are. Example: Certificate authority (verisign)
Integrity Adversary can not change contents of message But not necessarily private (public key) Example: secure checksum Freshness (read latest writes)
Privacy (confidentiality) Adversary can not read your message If adversary eventually breaks your system can they decode
all stored communication? Example: Anonymous remailer (how to reply?)
Authorization, repudiation (or non-repudiation), forward security (crack now, not crack future), backward security (crack now, not cracked past)
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What About Security in Distributed Systems?
Three challenges Authentication
Verify user identity Integrity
Verify that the communication has not been tempered with Privacy
Protect access to communication across hosts
Solution: Encryption Achieves all these goals Transform data that can easily reversed given the correct key (and
hard to reverse without the key)
Two common approaches Private key encryption Public key encryption
Cryptographic hash Hash is a fixed sized byte string which represents arbitrary length
data. Hard to find two messages with same hash. If m != m’ then H(m) != H(m’) with high probability. H(m) is 256 bits
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Private Key (Symmetric Key) Encryption
Basic idea: {Plain text}^K cipher text {Cipher text}^K plain text As long as key K stays secret, we get authentication, secrecy and
integrityInfrastructure: Authentication server (example: kerberos) Maintains a list of passwords; provides a key for two parties to
communicateBasic steps (using secure server S) A S {Hi! I would like a key for AB} S A {Use Kab {This is A! Use Kab}^Kb}^Ka A B {This is A! Use Kab}^Kb Master keys (Ka and Kb) distributed out-of-band and stored
securely at clients (the bootstrap problem)Refinements Generate temporary keys to communicate between clients and
authentication server
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Public Key Encryption
Basic idea: Separate authentication from secrecy Each key is a pair: K-public and K-private {Plain text}^K-private cipher text {Cipher text}^K-public plain text K-private is kept a secret; K-public is distributed
Examples: {I’m Emmett}^K-private
Everyone can read it, but only I can send it (authentication)
{Hi, Emmett}^K-public Anyone can send it but only I can read it (secrecy)
Two-party communication A B {I’m A {use Kab}^K-privateA}^K-publicB No need for an authentication server Question: how do you trust the “public key” server?
Trusted server: {K-publicA}^K-privateS
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Implementing your security goals
Authentication {I’m Emmett}^K-private
Integrity {SHA-256 hash of message I just send is …}^K-private
Privacy (confidentiality) Public keys to exchange a secret Use shared-key cryptography (for speed) Strategy used by ssh
Forward/backward security Rotate shared keys every hour
Repudiation Public list of cracked keys
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When you log into a website using an http URL, which property are you missing?
1. Authentication
2. Integrity
3. Privacy
4. Authorization
5. None
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Securing HTTP: HTTPS (HTTP+SSL/TLS)
client server CA
hello(client)
certificatecertificate ok?
switch to encryptedconnection using shared key
{send random shared key}^S-public
{certificate valid}^CA-private
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When you visit a website using an https URL, which property are you missing?
1. Authentication (server to user)
2. Authentication (user to server)
3. Integrity
4. Privacy
5. None
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Authentication
Objective: Verify user identity
Common approach: Passwords: shared secret between two parties Present password to verify identity
1. How can the system maintain a copy of passwords? Encryption: Transformation that is difficult to reverse without
right key Example: Unix /etc/passwd file contains encrypted
passwords When you type password, system encrypts it and then
compared encrypted versions
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Authentication (Cont’d.)
2. Passwords must be long and obscure Paradox:
Short passwords are easy to crack Long passwords – users write down to remember vulnerable
Original Unix: 5 letter, lower case password Exhaustive search requires 26^5 = 12 million comparisons Today: < 1us to compare a password 12 seconds to crack a
password Choice of passwords
English words: Shakespeare’s vocabulary: 30K words All English words, fictional characters, place names, words
reversed, … still too few words (Partial) solution: More complex passwords
At least 8 characters long, with upper/lower case, numbers, and special characters
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Are Long Passwords Sufficient?
Example: Tenex system (1970s – BBN) Considered to be a very secure system Code for password check:
Looks innocuous – need to try 256^8 (= 1.8E+19) combinations to crack a password
Is this good enough??
For (i=0, i<8, i++) {if (userPasswd[i] != realPasswd[i])Report Error;
}
For (i=0, i<8, i++) {if (userPasswd[i] != realPasswd[i])Report Error;
}
No!!! No!!!
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Are Long Passwords Sufficient? (Cont’d.)
Problem: Can exploit the interaction with virtual memory to crack passwords!
Key idea: Force page faults at carefully designed times to reveal password Approach
Arrange first character in string to be the last character in a page Arrange that the page with the first character is in memory Rest is on disk (e.g., a|bcdefgh) Check how long does a password check take?
If fast first character is wrong If slow first character is right page fault one of the later character is
wrong Try all first characters until the password check takes long Repeat with two characters in memory, …
Number of checks required = 256 * 8 = 2048 !!
Fix: Don’t report error until you have checked all characters! But, how do you figure this out in advance?? Timing bugs are REALLY hard to avoid
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Alternatives/enhancements to Passwords
Easier to remember passwords (visual recognition)
Two-factor authentication Password and some other channel, e.g., physical device
with key that changes every minute http://www.schneier.com/essay-083.html What about a fake bank web site? (man in the middle) Local Trojan program records second factor
Biometrics Fingerprint, retinal scan What if I have a cut? What if someone wants my finger?
Facial recognition
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Password security
1. Brute force password guessing for all accounts.
2. Brute force password guessing for one account.
3. Trojan horse password value
4. Man-in-the-middle attack when user gives password at login prompt.
Instead of hashing your password, I will hash your password concatenated with a random salt. Then I store the unhashed salt along with the hash. (password . salt)^H salt
What attack does this address?
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Authorization
Objective: Specify access rights: who can do what?
Access control: formalize all permissions in the system
Problem: Potentially huge number of users, objects that dynamically
change impracticalAccess control lists Store permissions for all users with objects Unix approach: three categories of access rights (owner, group,
world) Recent systems: more flexible with respect to group creation
Privileged user (becomes security hole) Administrator in windows, root in Unix Principle of least privlege
File1 File2 File3 …
User A RW R -- …
User B -- RW RW ..
User C RW RW RW …
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Authorization
Capability lists (a capability is like a ticket) Each process stores information about objects it has
permission to touch Processes present capability to objects to access (e.g., file
descriptor) Lots of capability-based systems built in the past but idea
out of favor today
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Enforcement
Objectives: Check password, enforce access control
General approach Separation between “user” mode and “privileged” mode
In Unix: When you login, you authenticate to the system by providing
password Once authenticated – create a shell for specific userID All system calls pass userID to the kernel Kernel checks and enforces authorization constraints
Paradox Any bug in the enforcer you are hosed! Make enforcer as small and simple as possible
Called the trusted computing base. Easier to debug, but simple-minded protection (run a lot of services in
privileged mode) Support complex protection schemes
Hard to get it right!
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Dweeb Nolife develops a file system that responds to requests with digitally signed packets of data from a content provider. Any untrusted machine can serve the data and clients can verify that the packets they receive were signed. So utexas.edu can give signed copies of the read-only portions of its web site to untrusted servers. Dweeb’s FS provides which property?
1. Authentication of file system users
2. Integrity of file system contents
3. Privacy of file system data & metadata
4. Authorization of access to data & metadata
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Summary
Security in distributed system is essential
.. And is hard to achieve!
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HTTPS (HTTP+SSL/TLS)
HTTP
TCP
IP
SSLhandshake cipher
Record
alert
Client and Server encrypt traffic usingShared keys established by handshake
protocol
